Method of making sideframes for railway car trucks

Information

  • Patent Grant
  • 6622776
  • Patent Number
    6,622,776
  • Date Filed
    Friday, December 22, 2000
    24 years ago
  • Date Issued
    Tuesday, September 23, 2003
    21 years ago
Abstract
The number of cores used in casting sideframes is reduced. A pair of end cores and a center core are placed in a mold with cope and drag portions. Each core includes integrally-formed portions for defining portions of the interior surfaces of the sideframes. The integrally-formed portions may include a portion for defining the side window of the sideframe formed integrally with other portions, and may include a pedestal portion formed integrally with other portions. The integrally-formed portions may contact both the cope and drag portions of the mold. The end cores may include integrally formed core prints for supporting the core in the mold. The integrally-formed portions of the center core include connections that are formed integrally with the other portions. Molten metal is introduced into the mold to cast the sideframe.
Description




BACKGROUND OF THE INVENTION




1. Field of the Invention




The present invention relates to three-piece railway car trucks, and more particularly, to a method of making sideframes for use in such three-piece railway car trucks.




2. Description of the Prior Art




In the past, in making hollow cast metal bodies, it has been known to use cores made of bonded sand supported in green sand molds to produce the hollow castings. The cores have been used to create the hollows or open spaces in the castings.




Cores have commonly been made in core boxes, typically having cope and drag halves that are brought together along a parting line. There is a cavity in the core box, and a mixture of sand and bonding material are introduced into the cavity and cured. The core box cope and drag portions are then parted along the parting line, generally being pulled apart vertically. Because of the need to pull the cope and drag portions apart, the sizes and shapes of the cores to be produced have been limited: the cores have not been able to have parts that would interfere with the movement of the cope portions away from the drag and with removal of the cores from the cope and drag portions. Thus, it typically has been necessary to produce several different cores that are later joined or placed together in the green sand mold.




In the case of cast metal sideframes for railway trucks, many different core shapes have been needed to produce the basic shape of the interior of the sideframes. As shown in

FIGS. 15-17

, more than twenty cores have been required, with some different cores sometimes adhered together in a separate process step before being placed in a receiving cavity in the mold, and with many different cores and groups of cores separately placed in the mold. While some cores such as a window core and bolster opening cores have been supported on core prints, many of the cores have been supported on chaplets on the mold surface. In addition to the placement of the cores being a labor intensive operation, the use of such multiple cores has been problematic from a quality control standpoint. With so many joints between the faces of the multiple cores, there is a potential for many fins to be formed on the interior of the casting. To remove these fins through a finishing operation has been difficult since the fins are on the interior of the casting. Moreover, these fins create another potential quality control problem since they could give rise to stress risers that could form along the fins. Other potential quality control problems arise from the potential for shifting of the cores' positions in the mold prior to or during the casting operation. If the cores shift position, the thickness of the walls of the casting could vary from the design.




In addition, multiple cores may be so thin that core rods are required to be used to support the sand. These core rods add to the cost of the process and complicate cleaning of the castings.




Another problem can arise in connection with areas of the sideframe around lightener holes and other openings in the sideframe wall. Metal fins can form around these openings, and sometimes form facing the interior of the casting. To finish such a casting by removing these fins may be difficult to accomplish manually since the fins are less accessible to the worker. In addition, it is very difficult to remove interior fins through automation.




Similar problems have arisen in producing cast metal bolsters for use in railway trucks. Like the sideframes, bolsters have hollow interiors, and have traditionally been made with multiple cores to form the interior walls and interior surfaces of the outer walls. Sixteen separate cores have been used to produce such castings, with cope and drag portions sometimes adhered to each other or juxtaposed along joints, as in the case of the sideframes cores, with chaplets supporting the cores on the mold surface, and with separate cores inserted into the cores to define holes for bolting side bearings and dead lever lugs to the bolster.




Similar problems as those outlined for sideframes have arisen with respect to quality control for bolsters. The positions of the cores on the chaplets may shift in the mold, creating the potential for making a casting with less than or more than desirable wall thicknesses. Bolster production has required that the multiple cores be placed in a mold in a labor intensive operation with multiple joints where stress risers could form. And like the sideframes, interior fins could form around lightener and other openings, fins that could be difficult and labor intensive to remove and that are not conducive to removal through automated finishing operations. Moreover, fins can form on the edges of the openings which can be stressed and damaged during the removal operation in the case of both sideframes and bolsters.




SUMMARY OF THE INVENTION




The present invention addresses various aspects of the prior art problems related to the production of cast metal sideframes for three-piece railway car trucks.




In one aspect, the present invention provides a method of making a hollow cast metal sideframe for a railway car. The sideframe has front and rear ends and a pedestal at each end. The sideframe also has a top member extending along a longitudinal axis between the front and rear ends, a tension member having a pair of diagonal portions and a center portion, a bolster opening in the middle of the sideframe between the top member and the center portion of the tension member, a pair of vertical columns along the bolster opening, and a pair of side windows. The sideframe has an inboard side and an outboard side. The pedestals, top member, tension member and columns have interior and exterior surfaces and widths between the inboard and outboard sides. The method comprises the steps of providing cores to define the hollow interior of the sideframe, providing a mold having cope and drag mold surfaces, placing the cores in the mold, and pouring molten metal into the mold to form a sideframe casting. In the improved method of the present invention, the cores include one core formed as an integral piece. This core has a core body that includes a column portion and a side window portion. The column portion defines an interior surface of one column across the width of the column. The window portion defines one side window and contacts both the cope and drag mold surfaces.




In another aspect, the present invention provides a method of making a hollow cast metal sideframe for railway cars. The sideframe has front and rear ends and pedestals at each end for mounting the sideframe on wheelsets. Each pedestal includes a pedestal roof and an outer pedestal leg. The sideframe has a top member extending along a longitudinal axis between the front and rear ends, a tension member having a bottom center portion and a pair of diagonal portions extending from the bottom center portion toward the pedestal roofs, a bolster opening in the middle of the sideframe between the top member and the bottom center portion of the tension member, a vertical column on each side of the bolster opening, and a pair of side windows. The pedestal roofs, outer pedestal legs, top member, tension member and columns have interior and exterior surfaces. The method comprises the acts of providing cores to define the hollow interior of the sideframe, providing a mold, placing the cores in the mold, and pouring molten metal into the mold to form a sideframe casting. In the improved method of the present invention, the cores include an end core having a core body including a pedestal portion, a diagonal member portion, a column portion, a top member portion and a side window portion. The pedestal portion defines an interior surface of at least one of the pedestal roof and the outer pedestal leg of one pedestal. The diagonal member portion defines an interior surface of one diagonal portion of the tension member. The column portion defines an interior surface of one column. The top member portion defines an interior surface of the top member. The side window portion defines at least part of one side window. At least part of the pedestal portion and at least part of the side window portion are formed as integral parts of the end core.




In another aspect, the present invention provides a method of making a hollow cast metal sideframe for a railway car truck. The sideframe has front and rear ends and pedestals at each end for mounting on wheelsets. The sideframe also has a top member extending along a longitudinal axis between the front and rear ends, a tension member having a bottom center portion and a pair of diagonal portions extending from the bottom center portion toward the pedestals, a bolster opening in the middle of the sideframe between the top member and the bottom center portion of the tension member, and a vertical column on each side of the bolster opening. The columns and top member have interior and exterior surfaces. The method comprises the acts of providing cores to define the interior of the sideframe, providing a mold, placing the cores in the mold, and pouring molten metal into the mold to form a casting. In the improved method of the present invention, the cores include a center core having a bolster opening portion and an integral top member portion. The bolster opening portion defines the exterior surfaces of the columns at the bolster opening. The integral top member portion defines an interior surface of a portion of the top member. The top member center portion and the bolster opening portion are connected. The top member center portion, bolster opening portion and connection between them are formed as an integral core.




In another aspect, the invention provides a method of making a hollow cast metal sideframe for use in a railway car truck. The sideframe has front and rear ends and pedestals at each end for mounting on wheelsets. The sideframe also has a top member extending along a longitudinal axis between the front and rear ends, a tension member having a bottom center portion and a pair of diagonal portions extending from the bottom center portion toward the pedestals, a bolster opening in the middle of the sideframe between the top member and the bottom center portion of the tension member, a vertical column on each side of the bolster opening, and a pair of side windows. The columns, top member, tension member and pedestals have interior and exterior surfaces. The method comprises the acts of providing cores to define the interior of the sideframe, providing a mold, placing the cores in the mold and pouring molten metal into the mold to form the casting. In the improved method of the present invention, the cores comprise a center core and a pair of end cores. The center core comprises a core body having a longitudinal axis. The center core includes a bolster opening portion for defining the exterior surfaces of the columns at the bolster opening and an integral top member center portion for defining an interior surface of a portion of the top member. The top member center portion and the bolster opening portion are connected. Each end core comprises a core body having a pedestal portion, an integral diagonal portion for defining an interior surface of the diagonal portion of the tension member, an integral column portion for defining an interior surface of one column, an integral top member portion for defining an interior surface of the top member, and a side window portion. The center core is formed as an integral core and each end core is formed as an integral core.




In another aspect, the present invention provides a method of making a cast metal sideframe for a railway car truck. The sideframe has front and rear ends and pedestals at each end for mounting on wheelsets. The sideframe also has a top member that extends along a longitudinal axis between the front and rear ends. The sideframe has a tension member that has a bottom center portion and a pair of diagonal portions extending from the bottom center portion toward the pedestals. The sideframe has a bolster opening in the middle of the sideframe between the top member and the bottom center portion of the tension member. The sideframe has a vertical column on each side of the bolster opening. The top member has a top surface with a plurality of lightener openings. The sideframe has interior and exterior surfaces. The method comprises the steps of providing a mold having cope and drag mold surfaces, providing a core having a core outer surface for forming at least a part of the interior surface of the cast metal sideframe, placing the core in the mold, and pouring molten metal into the mold to form the cast metal sideframe. In the improved method of the present invention, the core includes at least one core print and a side window portion. The core print is connected to the core outer surface and corresponds in size, shape and position with one lightener opening to be produced in the top wall of the top member of the sideframe. The side window portion and the core print are formed as integral parts of the same core.




In another aspect, the present invention provides a method of making a hollow cast metal sideframe for a railway car truck. The sideframe has front and rear ends and pedestals at each end for mounting on wheelsets. A top member extends along a longitudinal axis between the front and rear ends of the sideframe. The sideframe also has a tension member with a bottom center portion and a pair of diagonal portions extending from the bottom center portion toward the pedestals. A bolster opening is in the middle of the sideframe between the top member and the bottom center portion of the tension member. A vertical column extends along each side of the bolster opening. The sideframe also has a pair of side windows. The method includes the act of providing a mold for producing the cast metal sideframe. The mold has cope and drag mold surfaces defining a mold cavity. The method also includes the acts of providing a core to be received in the mold cavity and including a core outer surface for forming a part of the inner surface of the cast metal sideframe, placing the core on the drag mold surface, and pouring molten metal into the mold to form the cast metal sideframe. In the improved method of the present invention, the core comprises an end core. The end core includes a core print support integral with the core outer surface and a side window portion. The side window portion defines a side window of the sideframe and contacts both the cope and drag mold surfaces. A locator boss extends out from at least one of the side window portion, the cope mold surface and the drag mold surface. At least one of the side window portion of the core and the cope and drag mold surface has a mating hole to receive the locator boss.











BRIEF DESCRIPTION OF THE DRAWINGS





FIG. 1

is perspective view of a railway car truck, with sideframes and a bolster.





FIG. 2

is a top plan view of a sideframe that may be made according to the present invention.





FIG. 3

is a side plan view of a sideframe made according to the present invention with parts shown in section.





FIG. 4

is an enlarged partial perspective view of the top member of the sideframe of FIG.


2


.





FIG. 5

is a cross-section taken along line


5





5


of FIG.


4


.





FIG. 6

is a top plan view of the four one-piece sideframe cores of the present invention in place in a drag mold flask with other cores shown for purposes of illustration.





FIG. 6A

is an enlarged partial cross-section of a portion of a sideframe core received within the cope and drag portions of a mold.





FIG. 7

is a perspective view of the four one-piece sideframe cores, showing the portions that are provided to rest against the drag side of the mold surface.





FIG. 7A

is a partial cross-section of the one-piece end core of

FIGS. 6-7

, showing the locator boss received in a mating hole in the drag mold surface.





FIG. 8

is an exploded perspective view of the four one-piece sideframe cores, showing the opposite side of cores shown in FIG.


7


.





FIG. 8A

is a partial cross-section of the central opening of the center core of

FIGS. 6-8

, showing lift arms engaging the core for lifting and moving the core.





FIG. 9

is a perspective view of one of the one-piece sideframe end cores of the present invention.





FIG. 10

is a partial perspective view of the sideframe bottom center core end of the diagonal tension arm portion of the sideframe end core of FIG.


9


.





FIG. 11

is a partial side plan view of one of the core prints of the core of FIG.


9


.





FIG. 12

is a perspective view of the bottom center core of

FIGS. 6-8

.





FIG. 13

is an enlarged partial perspective view of one end of the bottom center core of FIG.


12


.





FIG. 14

is a perspective view of the sideframe center core shown in

FIGS. 6-8

.





FIG. 15

is a perspective view of some of the multiple prior art sideframe cores replaced by the consolidated one-piece end core of the present invention.





FIG. 16

is a perspective view of some of the multiple prior art sideframe cores replaced by the one-piece sideframe center core of the present invention.





FIG. 17

is a perspective view of a part of the prior art cores replaced by the one-piece bottom center core of the present invention.





FIG. 18

is a partial cross-section of a sideframe made using the cores of the present invention, taken along the longitudinal centerline of the sideframe.





FIG. 19

is a partial cross-section of a sideframe made using the cores of the present invention, taken along the longitudinal centerline of the sideframe, showing the opposite side shown in FIG.


18


.





FIG. 20

is a partial perspective view of one of the columns, with parts broken away, showing a friction plate in place on one column, with the mounting nuts, bolts and washers shown in exploded view.





FIG. 21

is a cross-section taken along line


21





21


of FIG.


20


.





FIG. 22

is a side plan view of a prior art bolster, with part shown in cross-section.





FIG. 22A

is a partial top plan view of the prior art bolster of

FIG. 22

, showing the mounting of a dead lever lug on a flat area of the bolster.





FIG. 23

is a side plan view of a bolster made according to the present invention, with part shown in cross-section.





FIG. 23A

is a partial cross-section of a rib of the bolster of FIG.


23


.





FIG. 24

is a top plan view of the bolster of FIG.


23


.





FIG. 25

is a perspective view of a prior art core used in making the prior art bolster.





FIG. 26

is a perspective view of another prior art core used in making a prior art bolster.





FIG. 27

is a perspective view of another prior art core used in making the prior art bolster.





FIG. 28

is a perspective view of another group of prior art cores used in making the prior art bolster.





FIG. 29

is a perspective view of another group of prior art cores used in making the prior art bolster.





FIG. 30

is an exploded side plan view of the three one-piece bolster cores of the present invention.





FIG. 31

is a perspective view of the three one-piece cores of the present invention with the two one-piece end cores resting on the one-piece center core.





FIG. 32

is a perspective view of an embodiment of a one-piece bolster center core of the present invention.





FIG. 33

is a perspective view of another embodiment of a one-piece bolster center core of the present invention.





FIG. 34

is a top plan view of the bolster center core of FIG.


32


.





FIG. 35

is a cross-section of the bolster center core of

FIG. 34

, taken along line


35





35


.





FIG. 35A

is a partial cross-section along line


35


A—


35


A of FIG.


34


.





FIG. 36

is a perspective view of a one-piece bolster end core of the present invention.





FIG. 37

is another perspective view of the one-piece bolster end core of FIG.


36


.





FIG. 38

is a perspective view showing the three one-piece bolster cores of the present invention in place in the drag side of a mold flask.





FIG. 39

is a partial cross-section showing the position of one of the cores of the present invention relative to the cope and drag parts of a mold.





FIG. 40

is a perspective view of the drag side of a core box that may be used to make the sideframe center core.





FIG. 41

is a side view of a dead lever lug that may be used with the bolster of the present invention.





FIG. 42

is a top plan view of the dead lever lug of FIG.


41


.











DETAILED DESCRIPTION




A railway truck


10


that may utilize cast metal components of the present invention is illustrated in FIG.


1


. As there shown, a typical railway truck


10


includes a pair of wheelsets


12


, each wheel set having an axle


14


with a wheel


16


at the end of each axle


14


. The two wheelsets


12


support a pair of spaced, parallel sideframes


18


. The two sideframes


18


have longitudinal centerlines


19


and are spanned by a bolster


20


, which is received in a bolster opening


21


in the middle of each sideframe. The bolster rides on a springset


22


.




The present invention provides improved sideframes and bolsters, and methods of making such cast metal bodies, as well as cores to be used in making such cast metal bodies. Use of the method and cores of the present invention should be beneficial in simplifying the making of cast metal sideframes and bolsters, as well as in improving the quality and reducing the weight of such products. The principles of the casting method and core designs should also prove applicable to the production of other cast metal bodies.




The sideframes disclosed in U.S. Pat. No. 5,481,986, issued Jan. 9, 1996 to Charles P. Spencer, Franklin S. McKeown and Donald J. Lane and assigned to Amsted Industries Incorporated, Chicago, Ill., may be made in accordance with the principles of the present invention, and the disclosure of that patent is incorporated by reference herein in its entirety.




As shown in

FIGS. 2-5

, a sideframe


18


made in accordance with the present invention generally includes a top member


24


having a center portion


26


and two similar top end portions


28


connected with the center portion


26


through compression member portions


27


. At the front and rear ends


30


,


32


the sideframe has pedestal jaws or pedestals


34


to be mounted on a wheelset


12


as illustrated in FIG.


1


. Each pedestal includes an outer pedestal leg


29


, a roof


31


, an inner pedestal leg


33


and a journal bracket flange


35


.




Each sideframe


18


also includes a tension member or lower member


36


comprised of a bottom center portion


38


and two integral diagonal portions


40


each extending from the bottom center portion


38


toward the pedestals


34


. A spring seat


42


is on the bottom center portion


38


of the tension member


36


, between the bottom center portion


38


and top center portion


26


of the top member


24


. The middle of the sideframe has a lower bolster opening


44


above the spring seat


42


to receive the spring set as shown in FIG.


1


. The middle of the sideframe also has a bolster opening


21


between the lower bolster opening


44


and the top center portion


26


of the top member


24


to receive the end of the bolster


20


as shown in

FIG. 1. A

column


48


extends between the top member


24


and tension member


36


, along each side of the bolster opening


21


and lower bolster opening


44


. Each sideframe


18


also has two side windows


50


. Each side window


50


is between the bolster opening


21


or columns


48


and the pedestals


34


at the front and rear ends


30


,


32


of the sideframe


18


, between the end portions


28


of the top member


24


and diagonal arm portions


40


of the tension member


36


.




The illustrated sideframe


18


is hollow, with exterior


52


and interior


54


sides or surfaces of its cast metal walls


56


. There are a plurality of openings in the cast metal walls


56


, including lightener openings


58


in the top surfaces of the top member


24


. Other openings


60


are provided, for example, in the walls between the side windows


50


and the diagonal arm portions


40


of the tension member, between the side windows


50


and the top end portions


28


of the top member


24


, and in the lower surface of the center portion


26


of the top member


24


. The walls


56


at each opening have an edge


62


, as shown in

FIGS. 4-5

, that curves outwardly, that is, the edge


62


is convex.




As used herein, references to the “tension member”


36


and “diagonal portions”


40


of the tension member are not intended to include the journal bracket flanges


35


and inner pedestal legs


33


, shown in

FIG. 3

, unless otherwise noted.




As shown in

FIG. 5

, the illustrated edges have radii of curvature designated “r” and each illustrated edge has two centers of curvature designated “c


1


” and “c


2


”. The radii of curvature “r” are about one-half the thickness of the metal walls


56


, represented by the designation “x” in FIG.


5


. The centers of curvature c


1


and c


2


are aligned, with the outermost center of curvature c


1


at a distance less than “x” from the outer surface of the metal and the innermost center of curvature c


2


centered between the outer and inner surfaces of the metal wall. The distance “x” is less than “r” in the illustrated embodiment In the illustrated embodiment, the sideframe walls have thicknesses at the lightener openings of about one-half inch, and the radii of curvature of the edges


62


are about one-quarter inch, with c


1


positioned less than one-quarter inch from the outer surface and c


2


positioned one-quarter inch from the inner and outer surfaces. Alternatively, the cast metal wall could have a single center of curvature, with, for example, a radius of curvature greater than one-half the thickness of the metal, that is, greater than the distance “x” shown in FIG.


5


.




The curved edges


62


of the sideframes at the lightener openings


58


and other openings


60


are formed by the method of the present invention, using unique cores


64


having unique core prints


66


as illustrated in

FIGS. 6-14

. Each core


64


has a core print


66


corresponding with each lightener opening


58


, and other opening


60


in the walls


56


of the sideframe


18


may also have core prints as illustrated. Each core


64


has an outer surface


68


from which the core prints


66


extend outwardly. Each core print


66


includes a core print body


70


to be received in a mating cavity in a mold to produce the cast metal part. Thus, the core print bodies


70


may serve to support and properly position the core in the mold. Each core print body


70


is integral with the remainder of the core and is connected to the core outer surface


68


through a bridge or neck


72


. Each bridge or neck


72


has a thickness, designated “n” in

FIG. 11

, corresponding with the desired thicknesses of the walls


56


of the cast metal at the edges


62


. Each neck or bridge


72


has a circumference or perimeter that is spaced inward of the edges


73


of the core print that meet or mate with the mold surface. Each neck or bridge


72


forms one of the metal edges


62


in the casting, the inner circumference of the edge


62


being spaced inward from the juncture of the core print and mold so that any fin forming at the juncture of the core print and the mold is spaced from the inner circumference of the edge. Having such a neck or bridge is expected to be beneficial in ensuring that if a fin is formed during the casting process, it should form on the exterior of the casting instead of the interior, making it much simpler to remove the fin through machining or other operation. Moreover, the hole should not fin over and should not form on the edges of the opening which could be stressed, particularly if damaged during fin removal. In the illustrated embodiment the necks or bridges


72


are concave to form convex edges


62


.




In making such cores, core boxes having cope and drag portions may generally be used. Such core boxes are generally separated along a parting line to remove the formed core therefrom. To accommodate such removal where the parting line lies in a plane perpendicular to a plane through the centers of curvature of the neck or bridge


72


, the embodiment illustrated in

FIG. 11

provides a curved concave neck or bridge with a thickness “n” and with two aligned centers of curvature, designated “c


1


” and “c


2


”, each having a radius “r”. The two centers of curvature comprise circles lying outside or beyond a plane


71


through the junctures of the neck


72


and core print body


70


. at the edges


73


of the core prints that meet the mold surface. Alternatively, the bridge


72


could have a single center of curvature and a radius of curvature greater than one-half the thickness of the bridge “n”. With either embodiment, the core neck or bridge does not curve back upon itself in a manner that would interfere with movement of the core relative to the cope and drag parts of the core box. Instead, each juncture


73


is spaced a distance “d” from a plane


75


through the nearest aligned centers of curvature c


1


and c


2


The distance “d” is equal to the length of the radius of curvature less the distance x. It should be understood that the present invention is not limited to such curvatures; the neck or bridge could alternatively comprise a cylindrical surface, for example.




At other locations spaced from the parting line, it is not necessary that the necks or bridges be curved, have two centers of curvature, or have a radius of curvature of the neck greater than one-half the thickness of the neck. Thus, for example, in the cores for forming the bolster of the present invention, the radius of curvature for the necks or bridges may be on the order of one-quarter inch, with the thickness of the neck, between the outer surface of the core body and the core print body being less than about one-half inch to produce a cast metal body having walls with thicknesses of less than about one-half inch.




It may be desirable to vary the thickness of the walls of the sideframe, as will be understood by those of skill in the art, to minimize weight while achieving the desired strength. In the illustrated embodiment, the thicknesses of the walls vary, being on the order of about one-half inch in some areas and on the order of about three-quarters of an inch in other areas. The dimensions of the necks or bridges vary according to the desired thicknesses.




In the illustrated embodiment the lightener openings in the cast metal sideframe are slightly smaller than those shown in U.S. Pat. No. 5,481,986 to move the openings away from the radius joining the top wall and each sidewall. The illustrated lightener openings


58


in the top member


24


have widths ranging to a maximum of 3.24 inches. The lengths of the two lightener openings nearest the center of the top member are each about six and one-half inches long; each is spaced from the edge by 1.88 inches and from each other by a distance of about two inches. The end lightener hole is spaced 1.62 inches from each edge and does not extend to the outermost part of the outer pedestal leg


29


. However, beading around the openings is removed in using the wrap-around prints so that there should not be any weight gain.




Another aspect of the present invention may be seen in

FIGS. 6-8

, illustrating the core consolidation achieved in the method of the present invention. As there shown, the interior surface


54


of the walls of the sideframe top member, tension member and columns may be made using four cores: two one-piece sideframe end cores


80


, one one-piece sideframe center core


82


and one one-piece bottom center core


84


.




Each of the illustrated one-piece end cores


80


of the present invention have a core body


86


with a pedestal portion


88


for defining an interior surface of the sideframe pedestal


34


at the front


30


or rear


32


end of the sideframe. In the illustrated embodiment, the pedestal portion


88


defines the interior surface of the outer pedestal leg


29


; the one-piece end core also defines the interior surface of the pedestal roof


31


. An integral diagonal tension arm portion


90


serves to define an interior surface of the sideframe's diagonal portion


40


of the tension member


36


. A top member portion


92


of the one-piece end core


80


also extends from the pedestal portion


88


, and serves to define the interior surface of the top end


28


and compression member


27


portions of the top member


24


. The one-piece end core


80


also includes an integral side window support


94


between the diagonal tension arm portion


90


, the top portion


92


, and a column portion


96


. The side window support


94


serves to define one of the side windows


50


of the sideframe


18


, and as shown in

FIG. 9

, is connected to the diagonal tension arm portion


90


and top portion


92


of the core through necks or bridges


98


that define the openings


60


in the diagonal portion of the tension arm and underside of the compression portion


27


of the top member


24


. The column portion


96


serves to define the interior surface


54


of the column


48


of the cast sideframe.




The side window support


94


has flat surfaces


100


that extend outward beyond the outer surface


68


of the core body


86


. These flat surfaces


100


serve to support a part of the weight of the end core


80


on the mold, and lie in a plane spaced from the outer surface


68


of the core body


86


a distance of about one-half inch. Since this surface


100


on the drag side


102


of the core rests on the drag mold surface


103


of the mold cavity


104


, and since this surface


100


on the cope side


106


bears against the cope mold surface (designated


107


in

FIG. 6A

for the cope mold surface at the print


70


on the top member portion


92


), this spacing defines the thickness of the metal to be cast in this area of the sideframe. In the illustrated embodiment, these surfaces


100


on both sides


102


,


106


of the core lie in planes.




In the illustrated embodiment, as shown in

FIGS. 7 and 9

, the side window support


94


on the drag side


102


of the end core


80


also includes a locator boss


112


extending out from the flat support surface


100


. The locator boss


112


is received within a mating hole or opening


113


(

FIG. 7A

) in the drag mold surface


103


of the drag side of the mold to locate and support the core. The illustrated locator boss


112


has the shape of a frustum of a cone, that is, it has a slight draft for ease of making the core and ease of placement of the boss


112


in the mating hole


113


. In the illustrated embodiment, as shown in

FIG. 6

, the cope side


106


of the end core does not have a locator boss, although it should be understood that a cope side locator boss could be provided if desired, along with a mating hole in the cope side of the mold.




Each end core


80


is further supported on the drag mold surface


103


by the core prints


66


corresponding with the lightener openings


58


in the outer surface of the top member


24


. Another core print


118


is located at the bottom center core end


120


of the diagonal portion of the tension member. The core print bodies


70


are shaped to be received in mating openings


116


in the drag mold surface


103


and to support a portion of the weight of the end core on the drag mold surface and in mating openings


117


in the cope mold surface


107


(

FIG. 6A

) to stabilize and position the core with respect to the cope mold surface. The core prints


66


,


118


, side window supports


94


and locator boss


112


also serve to locate or maintain the position of the end core


80


in the mold during handling and, in combination with the contour of the mold surfaces


103


,


107


, to define the thickness of the metal to be cast, which may be about one-half inch grade C, B or B+ steel, for example, in the illustrated embodiment. In addition, the combination of the illustrated core prints


66


,


118


and side window support


94


can support the entire sideframe end core


80


on the drag mold surface


103


, without any support chaplets or other device to support or position the core.




The one-piece end cores


80


may be made as a single, integral piece by providing a core box (not shown) having cope and drag halves with surfaces defining the shape of the one-piece end core. As shown in

FIGS. 9 and 10

, a one-piece end core made with such a core box would have a parting line


130


in the plane of the longitudinal axis


110


of the core but would be free of joint lines. The interior surface


54


of a cast metal sideframe or other metal body would likewise be free from fins, joint lines or other type of witness mark other than a slight depression or witness mark perhaps at the parting line


130


and at the joints between the consolidated cores. As used herein, the expression “witness mark” is intended to be a generic expression encompassing fins and joint marks.




To facilitate placement of the one-piece end cores


80


in the mold, the pedestal lug lightener


131


shown in

FIG. 15

has been removed from the illustrated one-piece end cores since the presence of the lug lightener interferes with automated setting of the core in the mold. As shown in

FIG. 6

, the mold may contain a separate core


217


to define the shape of the pedestal opening, and the end core could not be placed in the mold with the core


217


in place if the lug lightener was retained.




Another feature of the present invention relates to providing a stepped joint to support and locate the bottom center core


84


on the two end cores


80


, free from any support chaplets or other extraneous device for supporting the weight of the sideframe bottom center core


84


. As shown in

FIGS. 8 and 10

, the bottom center core end


120


of each diagonal portion of the tension arm has a stepped surface. The stepped surfaces on the end cores include a weight support member


132


, a longitudinal limit member


134


and a lateral limit member


136


, all lying in different planes. As shown in

FIG. 12

, the two ends


138


of the bottom center core


84


have mating weight support members


140


, longitudinal limit members


142


and lateral limit members


144


, all comprising surfaces lying in different planes. In the illustrated embodiment, the weight support members


132


,


140


are substantially co-planar with the longitudinal axis


110


of the end cores and bottom center core, although, as will be understood by those in the art, the surfaces


132


,


140


and others may have a draft in accordance with standard foundry practice, and such draft surfaces are intended to be included within the expression “substantially co-planar” as used herein. The longitudinal limit members


134


,


142


lie in planes intersecting the longitudinal axis


110


and intersecting the planes of the weight support members


132


,


140


and lateral limit members


136


,


144


. The mating lateral limit members


136


,


144


lie in planes intersecting the planes of the weight support members


132


,


140


and may comprise a key, designated


137


in the illustrated end core, and keyway, designated


145


in the illustrated bottom center core; it should be understood that the key could be formed on the bottom center core and the keyway on the end core if desired.




As shown in

FIGS. 6-8

, when the end cores


80


and bottom center core


84


are assembled, the bottom center core weight support members


140


rest on and are supported by the end core weight support members


132


, and the bottom center core longitudinal limit members


142


and lateral limit members


144


are positioned by the end core longitudinal limit members


134


and lateral limit members


136


. Thus, the entire weight of the bottom center core


84


is supported by the end cores


80


on their weight support members


132


,


140


and relative movement between the cores


80


,


84


is limited by the longitudinal


134


,


142


and


136


, lateral


144


limit members. The bottom center core


84


has a core print portion


146


at the joint with the end core that mates with the print


118


at the bottom center core end


120


of the diagonal part


40


of the tension member


36


. Thus, the bottom center core may be supported and positioned above the drag mold surface


103


without support chaplets, since the core prints


66


,


118


,


146


and locator bosses


112


maintain the position of the end cores


80


and bottom center core


84


, and the mold may be moved and used without the cores shifting position and without using support chaplets or other supports or positioning devices. However, to keep the bottom center core from floating upward during pouring of the molten metal, it may be desirable to place chaplets on top of the bottom center core to bear against the cope mold surface


107


and thereby hold the bottom center core down when molten metal is introduced.




As shown in

FIGS. 6-7

, the junctures of the end cores and bottom center core are at or immediately past the curvature points of the tension members


36


, that is, the junctures are along the diagonal portions


40


of the tension members, near the bottom center portion


40


.




As shown in FIGS.


10


and


12


-


13


, the lateral limit surfaces


136


,


144


of the key and keyway are not perpendicular to the longitudinal limit members


134


,


142


, but are slightly askew so that the lateral limit surfaces


144


of the bottom center core may be formed substantially parallel to the parting line


143


(

FIG. 12

) of the bottom center core; the lateral limit surfaces


136


,


144


may have a draft in accordance with standard foundry practices, and such draft surfaces are intended to be included within the expression “substantially parallel”. This configuration facilitates removal of the bottom center core


84


from the core box.




The bottom center core


84


generally defines the shape of the interior surface


54


of the walls


56


of the bottom center portion


38


of the tension member


36


of the sideframe


18


. Openings or slits


147


in the bottom center core, shown in

FIG. 12

, define internal support ribs


150


in the bottom center portion


38


of the tension member


36


, as shown in

FIGS. 18 and 19

. Such support ribs


150


are shown in

FIGS. 18-19

and extend to the spring seat


42


as illustrated, and correspond with five spaced slits


147


in the bottom center core


84


. In the illustrated embodiment, all of the slits


147


are defined by spaced walls that lie in planes substantially parallel to the plane of the longitudinal axis


149


of the bottom center core


84


for ease of removal of the completed core from the core box.




It is generally to be expected that a casting made with the disclosed bottom center cores and end cores will have an internal witness mark corresponding with the junctions of or joints


150


,


152


,


156


between the cores. Because of the stepped surfaces at the joints


150


,


152


,


156


, these witness marks are longitudinally offset on the interior surfaces


54


of the walls


56


in the casting. Thus, considering the two sides of the casting defined by the plane of the longitudinal centerline


19


of the cast sideframe


18


, shown in

FIGS. 18-19

, the distances between the witness marks


152


and the transverse centerline


154


on one side of the longitudinal centerline


19


of the sideframe are greater than the distances between the witness marks


156


and the transverse centerline


154


on the opposite half of the casting. As shown in

FIGS. 18 and 19

, a casting having such offset witness marks


152


,


156


can be expected to have been made using cores with stepped surfaces at the joints between cores.




A one-piece sideframe center core


82


is illustrated in FIG.


14


. This core may generally be as described and shown in U.S. Pat. No. 5,481,986, although in the center core of the embodiment illustrated in the present application, the sideframe center core


82


and bottom center core


84


are separate elements rather than combined as disclosed in the issued patent. In addition, in the embodiment illustrated in

FIG. 14

, the column faces do not have lightener openings, but merely openings for bolts for connecting friction plates to the column faces.




The one-piece sideframe center core


82


of the embodiment illustrated in

FIG. 14

includes a bolster opening element or portion


158


corresponding with the bolster opening


21


in the cast sideframe


18


. The center core has a central longitudinal axis


159


. The bolster opening portion includes a pair of planar support print surfaces


160


that lie in planes substantially parallel to the longitudinal axis


159


of the center core and substantially parallel to the longitudinal axes


110


of the end cores


80


when combined with the end cores as shown in FIG.


6


. The planar support print surfaces


160


may rest on mating support print surfaces of the drag mold surface


103


to support a part of the weight of the center core on the mold and prevent molten metal flow into the area to become the bolster opening. At the ends of the two planar support print surfaces


160


are opposite column surfaces


162


which define the exterior side of the opposing faces


163


of the sideframe columns


48


. The core column surfaces


162


are substantially parallel to each other and have vertically aligned cylindrical elements


164


extending outwardly from the surfaces with parallel axes aligned along the core's longitudinal centerline


159


. These cylindrical elements comprise integral bolt hole pin cores. As shown in

FIG. 6

, when the center core


82


is combined with the two end cores


80


, the cylindrical elements or bolt hole pin cores


164


meet the column portions


96


of the end cores to define bolt holes


166


in the opposing faces of the columns


48


of the cast metal sideframes for attachment of friction plates to the columns as shown in FIG.


19


.




As shown in

FIG. 14

, the illustrated one-piece sideframe center core


82


includes an integral spring seat element or portion


170


to define the lower bolster opening


44


and top surface of the spring seat


42


in the sideframe. The bottom surface


172


of the spring seat element


170


is spaced above the bottom center core


84


, and together with mating surfaces


174


in the drag and cope mold surfaces


103


,


107


, define a cavity in which metal is cast to form the spring seat


42


. The spring seat element


170


also has planar support surfaces


176


which support a part of the weight of the center core element


82


on the drag mold surface


103


and mate with the cope mold surface


107


to assure proper positioning of the center core with respect to the mold surfaces.




The illustrated one-piece sideframe center core


82


also includes a top member center portion


178


that defines the interior surface


54


of the walls


56


comprising the center portion


26


of the top member


24


. Integral necks or bridges


180


join the top member center portion


178


of the center core


82


to the bolster opening portion


158


. The necks or bridges


180


correspond with openings


182


in the underside of the center portion


26


of the top member


24


, as shown in FIG.


3


.




The illustrated one-piece sideframe center core


82


may be made as a single integral piece by providing a core box with cope and drag portions surfaces defining the shape of the center core. The core may be made so that the longitudinal axis


159


comprises the parting line of the core box, with the resulting core being free from joints and having only a parting line


184


along its central longitudinal axis


159


. To produce any indentations or protrusions in the core body that could be damaged during removal from the core box, the core box may be provided with movable parts that can be retracted when the core is to be removed from the core box. Such a core box is illustrated in FIG.


40


. Automatic devices, such as pneumatic or hydraulic operated elements, may be used with the core boxes to move the movable parts as desired during the cycle. The core produced may only have a visible parting line on a portion of the core, such as along the central longitudinal axis


159


of the top member center portion


178


and necks or bridges


180


but not elsewhere.




A cast metal sideframe made using the illustrated sideframe center core


82


may be expected to have witness marks comprising either joint lines or fins


186


on the interior surface


54


of the walls


56


comprising the top member


24


, as shown in

FIGS. 18 and 19

, where the center core top member center portion


178


portion meets the end core top member portions


92


, as shown in

FIGS. 6-8

, but to be otherwise free of joint lines or fins in the areas of the sideframe defined by the center core


82


. In addition, the center core


82


may be supported on the drag mold surface


103


solely by the support surfaces


160


,


176


so that the cast metal in the area of the sideframe defined by the one-piece center core


82


has fewer chaplets; since there are no support chaplets, one side of the tension member bottom center


40


may be free from support chaplets, while the other side may have some location chaplets.




The one-piece sideframe center core


82


may also have gates


161


in the bolster opening element or portion


158


, for movement of molten metal as will be understood by those in the art. The illustrated gates are included for purposes of illustration only and, if included, should be sized, shaped and positioned according to standard casting practices.




A cast metal sideframe made using the four illustrated cores


80


,


82


,


84


may be expected to have witness marks


186


on the interior surface


54


of the walls


56


comprising the top member


24


, as shown in

FIGS. 17 and 18

, and the offset interior witness marks


152


,


156


in the tension member


36


, but the interior surface should be otherwise free of joint lines and fins in the areas of the sideframe defined by the center core


82


.




The advantages of using two such one-piece end cores


80


, one-piece center core


82


and one-piece bottom center core


84


can be seen from a comparison of the number of cores used in the prior art to produce the interior cavity of a sideframe. Prior art cores are illustrated in

FIGS. 15-17

.

FIG. 15

shows a typical prior art core arrangement for making an end of a sideframe; seven cores were needed to form each end of the sideframe, for a total of fourteen cores, compared to a total of two cores in the present invention. The prior art cores for the sideframe end included: cope and drag side frame window cores


190


,


192


to form the area of the side window


50


and column


48


interior; cope and drag side frame intermediate cores


194


,


196


to form a part of the top member and pedestal roof interior; cope and drag sideframe tension cores


198


,


200


to form the diagonal portions


40


of the tension member


36


; and an end core


202


to form the interior of a part of the pedestal


34


. These cores were not integral, but were juxtaposed or sometimes adhered together, with joint lines existing between each of the individual cores. This substantial number of cores used in the prior art has been problematic in several respects: automation of the process of setting the cores in the mold is difficult since there are several small pieces that need to fit together in the mold; and there could be quality control problems with the prior art cores: shifts and movements of the individual cores or imperfections in the fit between adjoining cores could produce interior fins during casting or could result in the varying thicknesses of the casting walls; and if two cores such as the cores


198


,


200


are not properly aligned, the metal casting may have a stepped or uneven surface at the juncture of the two parts. Multiple cores are often thin, requiring use of core rods to provide strength to the core. Removal of these core rods after the casting is formed adds to the cost of manufacture.




Similar disadvantages and problems arise in using the multiple cores for the prior art center portion of the sideframe. As shown in

FIGS. 16-17

, one example of prior art center cores generally required at least nine cores where the present invention provides two: a side frame bolster opening core


204


, four column pin cores


206


inserted into the bolster opening core, a spring seat core


208


and cope and drag bottom center cores


210


,


212


adhered together. The prior art also typically included a spring seat back up core (not shown) that was not integral with or adhered to another core.




It should be understood that several additional cores are required for adding various appendages to the sideframe although those other cores will not be addressed by this invention. For example, there may be separate rotation lug cores added to the center core, although such cores could also be consolidated into the sideframe center core. Moreover, an additional six cores (not shown) may be required in the manufacturing process. But even with these additional cores, the present invention consolidates twenty-three cores into four, reducing the total number of cores for making a sideframe from twenty-nine to ten. These additional cores may need to be supported by chaplets on the drag mold surface, and may require locator chaplets to secure their positions. Some of these additional cores that are used with the present invention are generally shown in

FIG. 6

, including the right and left journal cores


217


and right and left journal bracket cores


219


. In addition, bracket cores to form slots for brake beams on the inboard sides of the sideframes would still be used, and the right and left journal cores, right and left journal bracket cores and brake beam bracket cores may require use of weight-supporting or locating chaplets, so that the resulting sideframe would have some chaplets, although the number of chaplets and the problems associates with their use is greatly decreased with the present invention.




Thus, it can be seen that the present invention offers several advantages in making sideframes. By reducing the number of cores, any tendency for shifting of the multiple cores is reduced, reducing internal metal mismatches. The safeguard against shifting is enhanced in the present invention by the use of the locator bosses


112


on the end cores


80


and the stepped connections between the bottom center core


84


and the end cores that limit lateral and longitudinal movement. Similarly, the fit of the core prints


66


of the end cores in the mating areas of the cope and drag mold also stabilize the positions of the end cores and bottom center core. And since the four cores of the present invention are supported in the mold by the core prints, other cores and opening-defining parts, the castings can be made without support chaplets, increasing the efficiency of the manufacturing operation and minimizing the chance for shifting of the cores. In addition, the present invention minimizes the number of joint lines which normally result between the faces of multiple cores, to improve the appearance of the final casting, reducing the amount of preparatory or finishing work necessary to remove fins, and improving internal casting quality by eliminating or greatly reducing the potential for stress risers which tend to form along the entire joint line. And since the manpower required for proper placement of the four cores instead of twenty-three is substantially less, labor costs should be reduced. With fewer and larger cores, there is also a chance for automation of the assembly process. Moreover, as will be understood by those in the casting field, the tooling costs in creating a single mold, as well as the replacement and maintenance costs for retaining quality standards for each mold is substantial. It is expected that waste of mold sand will also be reduced with fewer cores being produced, further reducing costs. In addition, it is expected that with fewer cores and less relative motion between cores, there is a lower potential for sand particles to become dislodged and become inclusions in the finally-cast metal. Inclusions can potentially become stress concentration areas or simply result in an area on the casting that requires surface clean up. Another advantage of the present invention is in eliminating or reducing the need to use core rods to strengthen the cores, simplifying production and reducing costs.




Another advantage of the present invention is in the assurance of proper placement and alignment of core pieces. In the case of the one-piece center core


82


, the vertically aligned cylindrical elements


164


take the place of the column pin cores


206


. The column pin cores


206


have typically been inserted into the surface of the side frame bolster opening core


204


after the cores


204


,


206


have been formed, and there has been a potential for misalignment of the pin cores, resulting in bolt holes


166


in the final casting that may be angled, making it more difficult to insert a bolt through the hole. With the integral cylindrical elements


164


, the resulting bolt holes should always be properly aligned.




Another feature of the present invention relates to provision of a pair of radial drafts


220


on the end core column portions


96


as shown in FIG.


9


. As illustrated in

FIG. 20

, the facing exterior faces


163


of the columns


48


typically have bolt holes


166


for mounting friction plates


222


to the sideframe with bolts


224


. As shown in

FIG. 21

, washers


226


and nuts


228


are tightened against the interior surface


54


of the column portion of the sideframe. If the interior surface


54


of the column is uneven, irregular or offset, then less than the entire flange of the nut or washer contacts the surface


54


; during tightening, stresses could be concentrated at portions of the nut, resulting in breaking or bending of the nut or bolt, or a less than desirable clamping force holding the plates


222


in place. This problem could potentially occur in one-piece end cores having parting lines running through the bolt hole areas, as well as in multi-piece cores having separate cores adhered to or juxtaposed with each other at junctures or joints intersecting the bolt hole areas. To alleviate this potential problem, the present invention provides a pair of conical raised areas


220


on the column portions


96


of the end cores


80


. As shown in

FIG. 9

, each raised area


220


comprises a raised center


230


extending furthest out from the outer surface


68


of the surrounding planar face


232


of the column portion


96


core. Each raised area also includes a tapered surface


234


extending from the raised center


230


toward the outer surface


68


of the planar face


232


. The raised area has a circular outer periphery


235


that is spaced slightly above the planar face


232


. The outer diameter of each raised area is about two and one-half inches. The tapered surface


234


and center


230


are shaped as a cone. The angle of the illustrated tapered surface is small, being on the order of one-third to one-half degree. In the illustrated embodiment, there are two vertically-aligned raised areas


220


, and the parting line


110


of the core runs through the raised centers


230


of the two raised areas. When placed in the mold along with the other cores, the center of each raised area


230


of each end core contacts the free end of one of the vertically aligned cylindrical elements


164


to define the bolt holes


166


in the casting. Thus, as shown in

FIG. 21

, each bolt hole


166


in the casting is surrounded by a depression


236


in the interior


54


surface of the casting. The depression


236


has a circular edge


238


at or slightly below the interior surface


54


of the casting, and a tapered wall


240


extending between the edge


238


and the bolt hole


166


at the center of the depression. In use, the peripheral edge of the nut


228


or washer


226


should contact the tapered wall


240


of the depression around the entire circumference or perimeter of the nut or washer. Since the entire circumference of the nut or washer is in contact with the interior surface of the side frame, there should be no bending moment on the nut and no lessening of the clamping force or torque. Instead, use of the present invention should result in symmetrical loading of the washer and nut. It should be understood that the principle of this feature of the invention should be applicable to any setting where a bolted connection is to be made where there is also a core or mold parting or joint line intersecting the site for the bolted connection. It should also be understood that the slope of the tapered surfaces of the core raised area and casting may generally be relatively small.




Many of the above principles can be applied to improve hollow cast metal bolsters


20


as well. As shown in

FIGS. 30-31

, a bolster


20


can be made with three consolidated cores defining its interior: a one-piece center core


300


and two one-piece end cores


302


supported on the center core


300


. Other standard cores, such as two spring cores, four pocket cores and a top center pin core, would still be required to be used to complete the bolster.




The bolster


20


, as shown in

FIGS. 23 and 24

, has a center


304


, two outboard ends


306


, a top wall


308


, and parallel side walls


310


extending down from the top wall


308


. Each illustrated side wall


310


has four large, spaced holes


312


, and each hole has an overall length and width. The bolster has an interior and the top wall


308


has an interior surface


314


and an exterior surface


316


. The side walls


310


also have interior surfaces


318


and exterior surfaces


320


. The bolster


20


has a central longitudinal axis


322


running from one outboard end


306


to the opposite one, and a central transverse axis


324


. The bolster


20


also has a bottom wall


326


and interior walls


328


. The bottom wall


326


in the illustrated embodiment extends between the sidewalls


310


, and can have openings or holes (not shown) communicating with the interior of the bolster.




The bolster


20


also has a center bore


330


through the top wall


308


. The central longitudinal axis


322


and central transverse axis


324


intersect at the center bore


330


. Two sets of bolt holes


331


are provided for mounting side bearings to the bolsters.




Within the interior of the illustrated embodiment of a bolster, there are longitudinal ribs


328


extending longitudinally between the interior surface


314


of the top wall


308


and the bottom wall


326


, and transverse support ribs


334


extending transversely between the longitudinal ribs


328


.




As shown in

FIGS. 23-24

, each longitudinal rib


328


has opposite faces


336


,


338


, and each transverse rib


334


has opposite faces


340


,


342


. In the illustrated embodiment, at least one of each pair of faces


336


,


338


,


340


,


342


is generally perpendicular to the plane of the top wall


308


of the bolster and remains generally perpendicular to that wall throughout its entire height. Similarly, the faces


340


,


342


of the illustrated transverse ribs


334


are generally parallel to the transverse axis or plane


324


throughout their entire height, from the interior surface


314


of the top wall


308


to the interior surface


344


of the bottom wall


326


. At least one of the opposite faces


336


,


338


of the longitudinal ribs


328


is generally parallel to the central longitudinal axis or plane


322


throughout its entire length. The central longitudinal axis


322


and transverse axis


324


lie in vertical planes, and at least one of the illustrated opposite faces


336


,


338


,


340


,


342


of the longitudinal ribs


328


and transverse ribs


334


is generally vertical throughout its entire length.




In contrast, in the prior art bolster illustrated in

FIG. 22

, the transverse support ribs


346


had faces


348


,


350


that were both angled throughout a portion of their heights. These faces


348


,


350


were both in non-vertical planes that intersected the vertical plane of the central transverse axis


324


. These angled transverse ribs


346


prohibited making a one-piece center core for the bolster, since such a core could not be removed from the core box without damage to the core. Instead, multiple cores, as shown in

FIG. 28

, were needed to produce the central portion of the bolster.




In this aspect of the present invention, all of the interior transverse rib faces have been aligned to allow a one-piece core to be made and used without sacrificing the desired physical characteristics of the bolster. Although the interior ribs may thin or thicken between the top and bottom walls, the change is on one side of the parting line for the one piece core, and only one face of the wall changes direction on that side of the parting line. And while the interior ribs made with a one piece core may have draft faces, on each side of the parting line the faces do not diverge from a vertical plane in the same direction. Thus, as shown in

FIGS. 23 and 23A

, in the top portion


337


of the bolster, from the top wall


308


down, the faces


336


,


338


,


340


,


342


of the longitudinal and transverse ribs do not diverge in the same direction from a vertical plane


341


between them and parallel to one of the longitudinal or transverse axes or planes


322


,


324


, and in the bottom portion


339


of the bolster, up from the bottom wall


326


to the top portion, the faces


336


,


338


,


340


,


342


of the longitudinal and transverse ribs do not diverge in the same direction from a vertical plane between them and parallel to one of the longitudinal or transverse axes or planes


322


,


324


. The top and bottom portions


337


,


339


are defined by a line


343


, shown in

FIG. 23A

, corresponding with the parting line


406


of the center core used to make the bolster, shown in FIG.


30


.




The multiple prior art cores needed to produce a prior art bolster are illustrated in

FIGS. 25-29

. As shown in

FIG. 29

, two sets of cope and drag end cores


360


,


362


were required to make the central part of the bolster, joined along a joint line


364


. Right and left collar cores


366


, shown in

FIG. 25

, were needed to form the center bowl or plate


368


(shown in FIG.


22


). An additional lug core


370


, shown in

FIG. 26

, was used to form lug holes in the side wall for attachment of a brake beam dead lever lug to the bolster. Two sets of cope


372


and drag


374


center cores, shown in FIG.


28


. These center cores


372


,


374


were also joined along joint lines


376


. As in the case of the sideframe cores, these cores were supported on the drag mold surface by chaplets. Thus, there was a potential for shifting of the cores, and control of the thicknesses of the metal walls became problematic. In addition, with all of the joint lines, there was a potential for stress risers to form in the casting.




As shown in

FIG. 27

, the prior art also used four separate pin cores


378


to be attached to the cope parts


360


of the end cores to form holes


331


for attachment of side bearings to the bolster. There was the potential for the pin cores


378


to be attached off-axis, creating the potential for undesirable stress on the bolts for attaching the side bearings to the bolsters.




In this aspect of the present invention, these sixteen prior art cores have been consolidated into three cores, shown in

FIGS. 30-39

. In both the embodiments of

FIGS. 32 and 33

, the one-piece center core


300


has a center core body


380


to be received in a mold cavity for defining the interior surfaces


314


,


318


,


344


of parts of the top


308


, side


310


and bottom


326


walls of the bolster, as well as parts of the longitudinal ribs


328


and transverse ribs


334


. The center core body


380


has a central longitudinal axis


382


and a central transverse axis


383


, as well as outer surfaces


384


to define the interior surface


318


of the sidewalls


310


. Outboard of the outer surfaces


384


are two core prints


386


. The core prints


386


are integral with the center core body


380


, and serve to support and position the center core in the drag mold


387


so that no support chaplets are required. The inner surfaces


455


of the core prints (

FIGS. 34

,


35


) also serve to define a portion of the exterior surfaces


320


of the bolster sidewalls


310


. Spaced surfaces


381


(

FIG. 39

) in the receiving mold also define portions of the exterior surfaces of these sidewalls. The core prints


386


are connected to the center core body


380


through necks or bridges


388


corresponding in size, shape and position with the holes


312


in the sidewalls.




The center core body


380


and center core prints


386


have lengths sufficient to span across the widths of all of the necks or bridges


388


on one side of the center core body. The center core prints


386


have heights sufficient to span across the heights of all the necks or bridges


388


on the center core body


380


. In the illustrated embodiments, the core print heights are also great enough to extend to a pair of holes


390


(

FIGS. 31-33

) in the print and aligned with holes in the core body


380


to receive cylindrical cores to define the dead lever lug holes. The heights of the core prints vary with the heights of the adjacent necks or bridges across the lengths of the core prints.




As shown, each embodiment of the core prints


386


has a central zone


392


and two end zones


394


. The central zone


392


and end zones


394


have stepped top surfaces


396


and stepped bottom surfaces


398


, and the heights of the central zones


392


of both embodiments are greater than the heights of the end zones


394


.




The central zones


392


of both core prints


386


have a height great enough and are wide enough to form part of the center plate or bowl


393


(

FIGS. 23

,


24


) of the bolster. As shown, the center plate forming parts


400


are integral with the core prints


386


. At the core prints' end zones


394


, the top surfaces


396


and bottom surfaces


398


are stepped toward each other, away from the top and bottom surfaces at the central zone. The top surface


396


may have also two steps, as shown in

FIG. 33

, or a single step as shown in FIG.


32


. In either embodiment the different levels of the top and bottom surfaces may be joined by angled or draft surfaces


402


that ease removal of the bolster center core from the core box. The drag


387


and cope


403


mold surfaces are formed to have recesses that mate with the shapes of the core prints so that the core prints may be easily placed in the mold.




The bottom surfaces


398


of the core prints


386


comprise weight support surfaces parallel with the top surfaces of the core prints. The total surface areas of the two weight support surfaces of the core prints and mating surfaces of the drag mold surface are great enough to support the entire center core on the drag mold surface


387


free from support chaplets. The weight support surfaces lie in planes that intersect the longitudinal axis


382


of the center core. The draft surfaces


402


of the core prints and mating surfaces of the cope mold may comprise positioning surfaces that lie in planes intersecting the top surfaces and bottom surfaces


396


,


398


of the core prints. The draft surfaces


402


may thus serve to limit longitudinal movement of the core body


380


in the mold. The end faces


407


of the core prints, received against mating faces in the drag mold, may also serve to limit longitudinal movement of the center core. The outer surfaces


404


of the core prints and mating surfaces in the drag mold perpendicular to the top


396


, bottom


398


and draft


402


surfaces may control lateral movement of the center core with respect to the drag mold portion


387


.




The one-piece center core


300


is free from joint lines, but has a parting line


406


with segments that intersect the vertical plane of the central transverse axis


382


,


383


. The center core body


380


has a top portion


408


on one side of the parting line


406


and a bottom portion


409


on the opposite side of the parting line


406


. As shown in

FIGS. 32 and 33

, the parting line


406


does not intersect the end faces


407


of the core, since it is preferred that the end faces


407


not have a draft above the parting line that would create a gap in the mold. Instead, the parting line goes to the top surface


396


of the end zone at the end face


407


and then down again.




The center core body


380


has a plurality of interior surfaces


412


, with pairs of them spaced apart to define slits for forming the longitudinal ribs


328


and transverse ribs


334


of the bolster


20


. As shown in

FIGS. 34 and 35

, to facilitate removal of the core from the core box, no two adjacent surfaces on one side of the parting line


406


diverge from a vertical plane parallel to the transverse or longitudinal axis


382


,


383


in the same direction; this design allows the core to be made in one-piece with a cope and drag core box pulled apart on the parting line


406


.




As will be understood by those in the art, the interior surfaces


412


of the bolster center core may have drafts to facilitate removal of the core from the core box. However, the core will not have back drafts that would be damaged in removing the core from the core box if, as shown in

FIG. 35A

, no two adjacent surfaces


412


on one side of the parting line


406


diverge in the same direction from a vertical plane


401


between them and parallel to one of the longitudinal or transverse axes


382


,


383


of the core.




The necks or bridges


388


connecting the core body and the core prints


386


may be concave curves, like the necks or bridges for the embodiment of the sideframe end cores illustrated in

FIG. 11

, so that the resulting bolster has convex surfaces at the edges surrounding the holes


312


. As in the sideframe end cores, as shown in

FIG. 35

the bolster core necks


388


may comprise inwardly curved surfaces with one or more centers of curvature designated “c” lying in a line around the exterior of the neck or bridge, beyond the junctures


411


of the necks and prints, as in

FIG. 11

embodiment for the sideframe. As in the sideframes, the thicknesses of the necks


388


correspond with the desired thickness of the walls of the cast bolster in that area. As in the sideframe, the radius of curvature may be greater than or equal to one-half the thickness of the neck or bridge. In the illustrated embodiment, the radius of curvature of the necks is less than one-half the thickness “n” of the necks, being about three-sixteenths of an inch for a metal thickness of one-half inch to meet the adjoining draft surfaces of the core print interior


455


and core body exterior


384


.




As shown in

FIG. 22A

, prior art bolsters frequently used a flat raised mounting area


457


on the exterior of the sidewall


461


for mounting a dead lever lug


463


to the bolster. Such flat raised mounting areas have provided a level mounting for the dead lever lugs, that is, for the mounting bracket for the railcar braking mechanism, in an area where the sidewall is angled. However, to provide such a flat raised mounting area on a bolster made with a one-piece center core is problematic: to avoid creating a step which would prohibit removing the one piece core from the core box, the mounting area would have to extend to the parting line, but this would add to the weight of the casting. Instead, in the present invention, the area of the bolster sidewall


310


where the dead lever lug is to be mounted does not have a flat mounting area; the area of the bolster sidewall is instead angled, as seen in

FIG. 24

, and the dead lever lug is similarly angled for mounting on the bolster sidewall, as shown in

FIGS. 41 and 42

.




As shown in

FIGS. 41 and 42

, a dead lever lug


413


for use with the illustrated bolster has two arms


415


,


417


angled to mate with the angle of the bolster sidewall. The illustrated dead lever lug arms


415


,


417


are spaced apart with a gap


419


between them. The gap


419


spans the radius on the bolster sidewall where the sidewall is angled. The arms


415


,


417


may also be angled in another direction to mate with any draft in the sidewall.




In another aspect, the one-piece center core


300


for the bolster may have two stepped outboard ends


414


,


416


opposite from the transverse center line


383


for supporting the end cores


302


. Each of the two outboard ends


414


,


416


of the bolster has a weight support member


418


, a longitudinal limit member


420


, and a lateral limit member


422


all lying in different planes. As shown in FIGS.


30


and


35


-


36


, the two inboard ends


424


of the end cores


302


have mating weight support members


426


, longitudinal limit members


428


and lateral limit members


430


, all comprising surfaces lying in different planes. In the illustrated embodiment, the weight support members or surfaces


418


,


426


are perpendicular to the planes of the longitudinal axis


382


of the core body. The mating longitudinal limit members


420


,


428


lie in planes parallel to the plane of the transverse center line


383


and the mating lateral limit members


422


,


430


lie in planes parallel to the longitudinal axis


382


of the core body. The mating lateral limit members


422


,


430


may comprise a key at each end


414


,


416


of the center core and a mating keyway in the ends


424


of the end cores, as shown in

FIGS. 31-34

and


36


-


37


.




As shown in

FIGS. 30-31

and


38


, when the three cores


300


,


302


are assembled the interior or inboard ends


424


of the end cores


302


are supported by the outboard ends


414


,


416


of the one-piece center core


300


. Each end core


302


also has an outboard end


432


that rests on and is supported by a part of the drag mold surface


387


when the three cores are placed in a mold. The drag mold


387


and outboard ends


432


of the end cores may have mating surfaces to ensure proper placement of the cores in the mold and the cope mold may also have mating surfaces to stabilize the positions of the outboard ends


432


of the two end cores. As shown in

FIG. 38

, gating or gas relief cores


433


may also be provided at the outboard ends


432


of the end cores. With the end cores


302


thus supported and the center core


300


supported solely by the core prints


386


, all three cores may be supported above the drag mold surface free from support chaplets. In the illustrated embodiment, the top surfaces


396


of the end zones


394


are flush with the top surface


431


of the drag mold


387


so that the bottom surface of the cope mold may bear against the end zones


396


and hold down the core.




The end cores


302


may each be a one-piece integral core free from joint lines as illustrated in

FIGS. 36 and 37

. The end cores may have recessed areas


434


for forming the parts of the bolsters that ride on friction shoes on the sideframes, and as will be understood by those skilled in the art, the shape of the end cores will vary with the type of friction shoe to be used. As shown in

FIG. 38

, mating friction shoe cores


435


may be provided on the drag mold surface. In addition, as shown in

FIG. 38

, a center pin core


429


may also be provided at the center of the bolster center core. In each end core, parallel interior surfaces


436


define a central slit


438


along a central longitudinal axis


439


for forming one of the longitudinal ribs


328


of the bolster. Additional slits


437


are formed by parallel surfaces


439


at the inboard ends


424


of the end cores


302


and align with interior surfaces


412


of the bolster center core to form two additional longitudinal ribs


328


. Each end core


302


may have a parting line


440


but is free from any joint line.




Each end core


302


also has a pair of integral bolt hole cylinders


442


extending upwardly from the top surface


444


of the end core. The bolt hole cylinders are aligned transversely near the stepped inboard ends


424


of the end cores to provide the holes


331


for bolts for mounting side bearings to the bolster.




A bolster resulting from using the three cores of this aspect of the present invention can be expected to have a minimum number of interior fins or joint lines. The only interior fins or joint lines can be expected to be along the junctures of the center core


300


and end cores


302


. Any such fin or joint line is referred to herein generically as a witness mark. As shown in

FIG. 23

, there may be a pair of top witness marks


446


on the interior surface


314


of the top wall


308


, parts of the top witness marks


446


being perpendicular to the longitudinal axis


322


, part matching the shape of the key and keyway, and positioned between the center bore


330


and the side bearing bolt holes


331


. The interior surface


318


of each side wall


310


may have a pair of side witness marks


448


leading from the ends of the top witness marks


446


to the bottom wall


326


interior surface


344


. Each of the side witness marks


448


comprises a step-shaped line having a segment


450


parallel to the top wall interior surface


314


between two segments


452


perpendicular to the top wall interior surface


314


. A pair of spaced straight bottom witness marks


454


may extend across the interior surface


344


of the bottom wall


326


between the side witness marks


448


on opposite side walls. All of the witness marks correspond with the junctures of the mating ends


414


,


416


,


424


of the center core


300


and two end cores


302


. The interior surfaces of the walls of the bolster are otherwise free from joint lines and fins. All of the walls of the bolster may be expected to be free from support chaplets, although there may be chaplets to prevent flotation of the end cores during casting, and possibly to position a center core forming the center bore


330


.




The exterior sidewalls


310


of a bolster made in accordance with this part of the disclosure is defined in part by the interior surfaces


455


of the center core prints (

FIGS. 34

,


35


) and may be expected to bear some imprint of the perimeters of the core prints


386


on the exterior surfaces


320


of the side walls


310


. Thus, the elongated “plus” sign shape of the core prints


386


may be visible on the exterior of the casting as a witness mark.




The cores described above may be used to produce cast metal sideframes and bolsters by placing the cores in suitable drag molds formed of green sand or other material in the drag side of a flask. A suitable cope side of a flask may then be placed on the combination of the cores and drag flask.




For the sideframes, chaplets may be used to prevent floatation of the bottom center core and to support and locate other cores, such as the cores used to form recesses on the inboard sides of the sideframes to receive the ends of brake beams, the journal cores and other cores to cooperate with the one-piece end cores to form the complete pedestals


34


. Such other cores are illustrated generally in

FIG. 6

, showing the four cores of the present invention in position in a drag flask; the details of the other cores are not shown, as those cores may be made and used according to the prior art.




For the bolster, the one-piece bolster center core


300


may be supported against movement in all three directions without chaplets, being supported by the mating mold halves and core prints. Each of the two bolster end cores


302


may be supported at one end by the stepped and keyed joint with the center core, and the other end supported by the drag mold. While the bolster end cores do not need support chaplets, floatation chaplets may be provided to hold the end cores down during pouring. Pouring and venting areas will be provided according to standard foundry practices.




The combinations may be handled as has been done traditionally in the art, and in fact may be moved with a reduced chance for the cores to shift position. Molten metal may be introduced as has been done in the past. After the metal has cooled, the casting may be removed from the flask, and the cores may be removed from the flask using known methods, such as by shaking the casting. The casting may then be finished, either as has been done traditionally in metal casting operations or the finishing operation may be automated since any fins will have been moved to the exterior of the casting. The present invention includes the method of making cast steel sideframes, bolsters, and other cast metal bodies in accordance with known foundry principles, using the new cores as described, and preferably without support chaplets for the one-piece cores. Standard grades of steel for such products may be used in these processes.




The cores may generally be made in accordance with standard foundry practices. Generally, cope and drag core box portions may be provided, and if automated equipment, such as a blower, is used to fill the core boxes, the cope and drag portions may be provided with a plurality of vents for air escape during filling. The sand used to make the cores may be mixed with a known binding agent. A suitable binder system is available from the Foundry Products Division, Ashland Chemical Company division of Ashland Oil, Inc. of Columbus, Ohio. The binder is sold under the trademark “ISOCURE” and comprises two resins: a first part with having phenolformadehyde polymer blended with solvents and a second part having polymeric MDI (methylene bis-phenylisocyanate). The two liquid resins cure to a solid urethane resin. Generally, the phenolic resin first part combines with the polyisocyanate second part in the presence of an amine catalyst (triethylamine) to form the solid urethane. Mixing the resins with the sand should be as recommended by the manufacturer, and should follow standard practices, taking into account the quality of the original sand, whether the sand is fresh or recycled, and other factors. The binder ratio and binder percentage may be adjusted as recommended by the manufacturer. The core boxes for producing the cores may have vents placed and sized as recommended by the manufacturer. It should be understood that the present invention is not limited to any particular binder system, nor to any particular core box design or device for introducing the sand and binder mixture into the core boxes.




Standard industry practices for introducing the mixture of sand and binder may be used, including but not limited to blowing. As will be understood by those skilled in the art, any suitable commercially available equipment may be used for introducing the mixture and curing agent, if any, as well as any improvement in presently available equipment. The equipment should be compatible with the binder system, but otherwise the selection of equipment may vary depending on desired production schedules.




For the blower device used, the blow tube size and position will vary with the core. Blow tubes may be located above the deepest and heaviest sections of the core, with blow tube diameters varying in accordance with standard practice. A blow plate for the center core


82


may have a plurality of conduits with rubber ends for introducing the sand and binder mixture into the core box. The cope and drag portions of the core boxes will have vent areas through which air may escape as the sand and binder mixture is blown into the core box and through which the catalyst gas may escape. The position, number and areas of the vents should be according to standard practice and as recommended by the manufacturers or suppliers of the binder and catalyst and blower equipment.




In making a one-piece core such as the illustrated one-piece center core


82


for the sideframe, traditional cope and drag core boxes may not produce the desired design that has recesses or protrusions that would interfere with pulling the two core box halves apart and removing the core. With such cores, it may be necessary to use a core box such as the drag portion illustrated in FIG.


40


. As there shown, the core drag box


459


has movable walls


460


,


462


,


464


that may be moved inward during core production and then pulled outward during core removal, and a stationary wall


466


that is part of the drag. Thus, features such as the vertically-aligned cylindrical elements


164


may be formed by cylindrical recesses


468


in the movable side walls


460


,


464


and pulled out of the way when the completed core is to be removed from the box. Instead of moving the entire wall, it may also be desirable to have portions that move at different times during production. The walls or portions of walls may be moved by devices such as a pneumatic control


470


; in the illustrated embodiment, two pneumatic controls are provided, with lines


472


connected to power the controls


470


to move the walls


460


,


462


,


464


or portions of walls. Recesses in the core box walls may be provided with vents


473


, and as will be understood by those in the art, any equipment used to introduce the sand and binder mixture into the core box should be designed to ensure that all parts of the core box are filled with the sand and binder mixture. Some movable parts may also be needed in producing the one-piece bolster center core with holes; axially movable cylinders may be used to produce the holes


390


through the prints and later filled with cylindrical cores.




The one-piece cores produced in accordance with the principles disclosed herein may be expected to weigh a substantial amount and accordingly be difficult for a single worker to manipulate. Accordingly, it may be desirable to provide for automation in removing the cores from the core box and in transporting the cores. In addition, pallets may be provided to support the cores. Picker fingers or lift devices may be incorporated into the core box design to lift the core out of the box, and gantries may be provided for standard moving devices to lift and move the cores. The core designs may be modified to accommodate the particular lifting and moving devices and pallets to avoid damage to the surfaces of the core bodies. For example, it may be desirable to make the core prints large enough for a lifting or supporting device to bear against several portions of the cores instead of acting against the core body itself. And it may also be desirable to provide orifices or recesses in the core prints and core bodies to receive lifting devices for moving the cores as well as to lighten the cores and reduce the amount of sand and binder required to be used. As with the lifting devices, storing and moving devices selected may vary depending on many factors, the illustrated cores may be varied to accommodate the equipment available or selected.




Examples of variations in the core design to accommodate lifting and moving devices are illustrated in

FIGS. 6-8A

,


14


and


30


. As shown in

FIG. 30

, for example, each core print


386


on the bolster center core


300


may have a pair of recesses


500


defining a shelf


502


for receiving the end of a lifting device. As shown in

FIGS. 6-8A

and


14


, the sideframe center core


82


may have an central opening


504


with an interior shelf


506


as shown in

FIG. 8A

; thus, a group of lifting arms


508


can be used, each rotating about its central longitudinal axis


510


, with a perpendicular segment


512


that rotates to fit under the interior shelf


506


so that the core may be lifted. The lifting devices may then be rotated so that the perpendicular segments are no longer under the shelf when the core is deposited in its proper position on the drag mold, for example. Preferably, the lifting devices contact the cores in areas such as the prints to avoid harming the cores.




It should be understood that standard foundry practices should be used along with the disclosures of the present invention, such as providing chill plates where necessary for the best quality casting. It should also be understood that the illustrated cores do not necessarily show recesses to form the chill plates, and the absence of chill plates or recesses in a drawing should not be considered as a teaching that none are necessary or desirable. Similarly, where slits are shown in cores that may correspond with chill plates generally, it should be understood that the positions of the chill plates may be other than as shown, as the drawings are merely illustrative of such features.




Standard foundry practices may be used in washing and drying the cores. In accordance with standard foundry practices, various surfaces such as the longitudinal and lateral limit surfaces of the sideframe end, center and bottom center cores and bolster center and end cores, and various walls and ribs may have slight drafts incorporated into the design to facilitate removal of the cores from the core boxes.




For handling the finished cores in, for example, transferring the core from the core-making site to the site where the cores are placed in the mold, it may be desirable to provide pallets that are capable of supporting the combined cores.




While only specific embodiments of the invention have been described and shown, it is apparent that various alternatives and modifications can be made thereto. For example, although the cores have been shown shaped to produce particular railway truck parts, it should be understood that changes in shapes may be made for other types of railway trucks, and the invention is not limited to the illustrated style of railway truck. In addition, although the invention has been described with respect to particular core structures for producing railcar truck parts, the principles of the invention may be applied to the production of other cast metal structures. It is, therefore, the intention in the appended claims to cover all such modifications and alternatives as may fall within the true scope of the invention.



Claims
  • 1. In a method of making a hollow cast metal sideframe for a railway car,the sideframe having front and rear ends and a pedestal at each end, a top member extending along a longitudinal axis between the front and rear ends, a tension member having a pair of diagonal portions and a center portion, a bolster opening in the middle of the sideframe between the top member and the center portion of the tension member, a pair of vertical columns along the bolster opening, and a pair of side windows, the sideframe having an inboard side and an outboard side, the pedestals, top member, tension member and columns having interior and exterior surfaces and widths between the inboard and outboard sides, the method comprising the steps of providing cores to define the hollow interior of the sideframe, providing a mold having cope and drag mold surfaces, placing the cores in the mold, and pouring molten metal into the mold to form a sideframe casting; the improvement wherein the cores include one core formed as an integral piece and having a core body including: a column portion for defining an interior surface of one column across the width of the column; and a side window portion for defining one side window, the side window portion contacting both the cope and drag mold surfaces.
  • 2. The method of claim 1 wherein the integrally-formed core further comprises at least one of the following:a top member portion for defining the interior surface of the entire width of at least a part of the length of the top member; a portion for defining the interior surface of the entire width of at least part of the length of the tension member; and a portion for defining the interior surface of at least part of one pedestal; and wherein the entire core body is formed as an integral core.
  • 3. The method of claim 1 wherein the integrally-formed core further comprises all of the following:a top member portion for defining the interior surface of the entire width of at least a part of the length of the top member; a portion for defining the interior surface of the entire width of at least part of the length of the tension member; and a portion for defining the interior surface of at least part of one pedestal; and wherein the entire core body is formed as an integral core.
  • 4. The method of claim 2 wherein the integrally-formed core further comprises a core print connected to the core body, the core print and side window portion for supporting the weight of the core in the mold.
  • 5. The method of claim 3 wherein the integrally-formed core further comprises a core print connected to the core body, the core print and side window portion for supporting the weight of the core in the mold.
  • 6. The method of claim 5 wherein the core print includes a core print body and a reduced diameter neck connecting the core print body to the core body.
  • 7. The method of claim 1 wherein the integrally-formed core further includes a pair of raised conical areas on the column portion of the core body.
  • 8. The method of claim 3 wherein the integrally-formed core includes a stepped surface for supporting another core.
  • 9. The method of claim 1 wherein at least one of the core and the mold includes a locator boss and the other of the core and the mold includes a mating hole to receive the locator boss.
  • 10. In a method of making a hollow cast metal sideframe for railway cars,the sideframe having front and rear ends and pedestals at each end for mounting the sideframe on wheelsets, each pedestal including a pedestal roof and an outer pedestal leg, the sideframe having a top member extending along a longitudinal axis between the front and rear ends, a tension member having a bottom center portion and a pair of diagonal portions extending from the bottom center portion toward the pedestal roofs, a bolster opening in the middle of the sideframe between the top member and the bottom center portion of the tension member, a vertical column on each side of the bolster opening, and a pair of side windows, the pedestal roofs, outer pedestal legs, top member, tension member and columns having interior and exterior surfaces; the method comprising the steps of providing cores to define the hollow interior of the sideframe, providing a mold, placing the cores in the mold, and pouring molten metal into the mold to form a sideframe casting; the improvement wherein the cores include an end core having a core body including: a pedestal portion for defining an interior surface of at least one of the pedestal roof and the outer pedestal leg of one pedestal; a diagonal member portion for defining an interior surface of one diagonal portion of the tension member, a column portion for defining an interior surface of one column, a top member portion for defining an interior surface of the top member, and a side window portion for defining at least part of one side window; at least part of said pedestal portion and at least part of said side window portion being formed as integral parts of said end core.
  • 11. The method of claim 10 wherein said pedestal portion is formed integral with said diagonal member portion.
  • 12. The method of claim 10 wherein said pedestal portion is formed integral with said column portion.
  • 13. The method of claim 10 wherein said pedestal portion is formed integral with said top member portion.
  • 14. In a method of making a hollow cast metal sideframe for a railway car truck,the sideframe having front and rear ends and pedestals at each end for mounting on wheelsets, a top member extending along a longitudinal axis between the front and rear ends, a tension member having a bottom center portion and a pair of diagonal portions extending from the bottom center portion toward the pedestals, a bolster opening in the middle of the sideframe between the top member and the bottom center portion of the tension member, a vertical column on each side of the bolster opening, the columns and top member having interior and exterior surfaces, the method comprising the steps of providing cores to define the interior of the sideframe, providing a mold, placing the cores in the mold, and pouring molten metal into the mold to form a casting; the improvement wherein the cores include a center core having: a bolster opening portion for defining the exterior surfaces of the columns at the bolster opening, an integral top member portion for defining an interior surface of a portion of the top member, the top member center portion and the bolster opening portion being connected and, the top member center portion, bolster opening portion and connection being formed as an integral core.
  • 15. In a method of making a hollow cast metal sideframe for use in a railway car truck,the sideframe having front and rear ends and pedestals at each end for mounting on wheelsets, a top member extending along a longitudinal axis between the front and rear ends, a tension member having a bottom center portion and a pair of diagonal portions extending from the bottom center portion toward the pedestals, a bolster opening in the middle of the sideframe between the top member and the bottom center portion of the tension member, a vertical column on each side of the bolster opening, and a pair of side windows, the columns, top member, tension member and pedestals having interior and exterior surfaces, the method comprising the steps of providing cores to define the interior of the sideframe, providing a mold, placing the cores in the mold and pouring molten metal into the mold to form the casting; the improvement wherein the cores comprise: a center core comprising a core body having a longitudinal axis and including a bolster opening portion for defining the exterior surfaces of the columns at the bolster opening, an integral top member center portion for defining an interior surface of a portion of the top member, the top member center portion and the bolster opening portion being connected; and a pair of end cores, each end core comprising a core body having a pedestal portion, an integral diagonal portion for defining an interior surface of the diagonal portion of the tension member, an integral column portion for defining an interior surface of one column, an integral top member portion for defining an interior surface of the top member, and a side window portion; wherein the center core is formed as an integral core and wherein each end core is formed as an integral core.
  • 16. The method of claim 15 wherein the cores further include a bottom center core for forming an interior surface of the portion of the tension member between the ends of the two diagonal portions of the tension member.
  • 17. In a method of making a cast metal sideframe for a railway car truck,the sideframe having front and rear ends and pedestals at each end for mounting on wheelsets, a top member extending along a longitudinal axis between the front and rear ends, a tension member having a bottom center portion and a pair of diagonal portions extending from the bottom center portion toward the pedestals, a bolster opening in the middle of the sideframe between the top member and the bottom center portion of the tension member, a vertical column on each side of the bolster opening, and a pair of side windows, the top member having a top surface with a plurality of lightener openings, the sideframe having interior and exterior surfaces, the method comprising the steps of: providing a mold having cope and drag mold surfaces, providing a core having a core outer surface for forming at least a part of the interior surface of the cast metal sideframe, placing the core in the mold, and pouring molten metal into the mold to form the cast metal sideframe, the improvement wherein the core includes at least one core print connected to the core outer surface and corresponding in size, shape and position with one lightener opening to be produced in the top wall of the top member of the sideframe; and a side window portion; the side window portion and the core print being formed as integral parts of the same core.
  • 18. The method of claim 17 wherein the core print includes a core print body and a neck connecting the core print body to the core outer surface, the neck corresponding in size, shape and position with one lightener opening to be produced in the top wall of the top member of the sideframe.
  • 19. The method of claim 18 wherein the core print body has an edge meeting a mold surface and the neck has a perimeter inward of the edge of the core print body.
  • 20. The method of claim 17 wherein the side window portion contacts the cope and drag portions of the mold.
  • 21. The method of claim 17 wherein the side window portion and core print are capable of supporting the core in the mold without chaplets.
  • 22. In a method of making a hollow cast metal sideframe for a railway car truck,the sideframe having front and rear ends and pedestals at each end for mounting on wheelsets, a top member extending along a longitudinal axis between the front and rear ends, a tension member having a bottom center portion and a pair of diagonal portions extending from the bottom center portion toward the pedestals, a bolster opening in the middle of the sideframe between the top member and the bottom center portion of the tension member, a vertical column along each side of the bolster opening, a pair of side windows; the method comprising the steps of providing a mold for producing the cast metal sideframe, the mold having cope and drag mold surfaces defining a mold cavity, providing a core to be received in the mold cavity and including a core outer surface for forming a part of the inner surface of the cast metal sideframe, placing the core on the drag mold surface, and pouring molten metal into the mold to form the cast metal sideframe; the improvement wherein the core comprises an end core including: a core print support integral with the core outer surface; a side window portion for defining a side window of the sideframe, the side window portion contacting both the cope and drag mold surfaces; and a locator boss extending out from at least one of the side window portion, the cope mold surface and the drag mold surface; at least one of the side window portion of the core and the cope and drag mold surface having a mating hole to receive the locator boss.
Parent Case Info

This is a division of application Ser. No. 09/524,469, filed on Mar. 13, 2000 now U.S. Pat. No. 6,330,862 which is a division of application Ser. No. 09/357,061, filed on Jul. 19, 1999, now U.S. Pat. No. 6,089,166, which is a division of application Ser. No. 09/058,680, filed on Apr. 10, 1998, now U.S. Pat. No. 5,967,053, which is a division of application Ser. No. 08/780,546 filed on Jan. 8, 1997, now U.S. Pat. No. 5,752,564, the entire disclosures being part of the disclosure of this application and being hereby incorporated by reference herein.

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